Mirror of micropython/micropython@github.com - Python for microcontrollers
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Brian 'redbeard' Harrington 5fe2a3f14f esp32/CMake: Change PROJECT_DIR to CMAKE_CURRENT_LIST_DIR.
This migrates the CMake variable `MICROPY_PORT_DIR` from the ESP-IDF
defined project to the component. Previously used instances of the variable
within the project definition have been migrated to
`CMAKE_CURRENT_LIST_DIR`. Within the component (the `main` subdirectory in
the ESP32 port) we define `MICROPY_PORT_DIR` using `CMAKE_CURRENT_LIST_DIR`
and subsequently use the `MICROPY_PORT_DIR` value in all locations where
`PROJECT` had previously been used.

Context:

In commit 9b90882146, initial support was added for building with the newly
introduced CMake support provided by the ESP-IDF.

Specifically, the commit message states:

> This commit adds support for building the esp32 port with CMake, and in
particular, it builds MicroPython as a component within the ESP-IDF. Using
CMake and the ESP-IDF build infrastructure makes it much easier to maintain
the port, especially with the various new ESP32 MCUs and their required
toolchains.

`PROJECT_DIR` is a variable populated by the ESP-IDF specifically and is
not stable when used with "[Pure CMake components][1]" as documented in the
ESP-IDF. It is intended to be used in the scope of the parent of the
current file (the "project") as opposed to the current file ("the
component"). Crossing into the parent scope like this works solely when the
"project" is MicroPython, but not when used as a component by other ESP-IDF
projects.

Analyzing this file, the intention is to reference the "Project" which in
the example is the parent directory. Within the [CMake variables][2]
documentation, there is one specifically defined for referencing the
directory for the CMake listfile currently being processed:
[`CMAKE_CURRENT_LIST_DIR`][3].

After making the change from `PROJECT_DIR` to `CMAKE_CURRENT_LIST_DIR`, the
reach into the parent scope defined by the ESP-IDF and the resulting CMake
interface violation is removed.

Similar to the component definition, the project `CMakeLists.txt` uses the
variable `CMAKE_SOURCE_DIR` which CMake defines as "The path to the top
level of the source tree."  This commit changes the variable to
`CMAKE_CURRENT_LIST_DIR` for the reasons cited above.

[1]: https://docs.espressif.com/projects/esp-idf/en/latest/esp32s2/api-guides/build-system.html#writing-pure-cmake-components
[2]: https://cmake.org/cmake/help/latest/manual/cmake-variables.7.html
[3]: https://cmake.org/cmake/help/latest/variable/CMAKE_CURRENT_LIST_DIR.html

Signed-off-by: Brian 'redbeard' Harrington <redbeard@dead-city.org>
2023-06-13 00:11:05 -07:00
.github github/workflows: Force use of Ubuntu-20.04 for unix 32-bit builds. 2023-05-18 13:12:40 +10:00
docs docs/library/index: Update docs after umodule rename. 2023-06-08 17:54:28 +10:00
drivers samd/samd_qspiflash: Add QSPI flash driver and configure it accordingly. 2023-06-06 00:49:36 +10:00
examples all: Replace all uses of umodule in Python code. 2023-06-08 17:54:24 +10:00
extmod extmod/modtimeq: Remove timeq module. 2023-06-08 17:54:28 +10:00
lib lib/fsp: Update FSP for renesas-ra to the latest version v4.4.0. 2023-05-11 16:18:39 +10:00
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mpy-cross
ports esp32/CMake: Change PROJECT_DIR to CMAKE_CURRENT_LIST_DIR. 2023-06-13 00:11:05 -07:00
py py/mkrules.mk: Automatically configure frozen options when manifest set. 2023-06-08 23:12:56 +10:00
shared py/modsys: Allow sys.path to be assigned to. 2023-06-08 17:54:24 +10:00
tests extmod/modtimeq: Remove timeq module. 2023-06-08 17:54:28 +10:00
tools tools/mpremote: Fix exec_ -> exec in commands.py. 2023-06-09 13:36:12 +10:00
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ACKNOWLEDGEMENTS
CODECONVENTIONS.md CODECONVENTIONS: Require that commits be signed-off by the author. 2023-05-08 12:20:56 +10:00
CODEOFCONDUCT.md
CONTRIBUTING.md
LICENSE LICENSE: Move wiznet5k entry from drivers to lib. 2023-06-02 17:48:31 +10:00
README.md
pyproject.toml top: Add "mis" to list of ignore words for codespell. 2023-06-06 10:23:44 +10:00

README.md

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The MicroPython project

MicroPython Logo

This is the MicroPython project, which aims to put an implementation of Python 3.x on microcontrollers and small embedded systems. You can find the official website at micropython.org.

WARNING: this project is in beta stage and is subject to changes of the code-base, including project-wide name changes and API changes.

MicroPython implements the entire Python 3.4 syntax (including exceptions, with, yield from, etc., and additionally async/await keywords from Python 3.5 and some select features from later versions). The following core datatypes are provided: str(including basic Unicode support), bytes, bytearray, tuple, list, dict, set, frozenset, array.array, collections.namedtuple, classes and instances. Builtin modules include os, sys, time, re, and struct, etc. Select ports have support for _thread module (multithreading), socket and ssl for networking, and asyncio. Note that only a subset of Python 3 functionality is implemented for the data types and modules.

MicroPython can execute scripts in textual source form (.py files) or from precompiled bytecode (.mpy files), in both cases either from an on-device filesystem or "frozen" into the MicroPython executable.

MicroPython also provides a set of MicroPython-specific modules to access hardware-specific functionality and peripherals such as GPIO, Timers, ADC, DAC, PWM, SPI, I2C, CAN, Bluetooth, and USB.

Getting started

See the online documentation for API references and information about using MicroPython and information about how it is implemented.

We use GitHub Discussions as our forum, and Discord for chat. These are great places to ask questions and advice from the community or to discuss your MicroPython-based projects.

For bugs and feature requests, please raise an issue and follow the templates there.

For information about the MicroPython pyboard, the officially supported board from the original Kickstarter campaign, see the schematics and pinouts and documentation.

Contributing

MicroPython is an open-source project and welcomes contributions. To be productive, please be sure to follow the Contributors' Guidelines and the Code Conventions. Note that MicroPython is licenced under the MIT license, and all contributions should follow this license.

About this repository

This repository contains the following components:

  • py/ -- the core Python implementation, including compiler, runtime, and core library.
  • mpy-cross/ -- the MicroPython cross-compiler which is used to turn scripts into precompiled bytecode.
  • ports/ -- platform-specific code for the various ports and architectures that MicroPython runs on.
  • lib/ -- submodules for external dependencies.
  • tests/ -- test framework and test scripts.
  • docs/ -- user documentation in Sphinx reStructuredText format. This is used to generate the online documentation.
  • extmod/ -- additional (non-core) modules implemented in C.
  • tools/ -- various tools, including the pyboard.py module.
  • examples/ -- a few example Python scripts.

"make" is used to build the components, or "gmake" on BSD-based systems. You will also need bash, gcc, and Python 3.3+ available as the command python3 (if your system only has Python 2.7 then invoke make with the additional option PYTHON=python2). Some ports (rp2 and esp32) additionally use CMake.

Supported platforms & architectures

MicroPython runs on a wide range of microcontrollers, as well as on Unix-like (including Linux, BSD, macOS, WSL) and Windows systems.

Microcontroller targets can be as small as 256kiB flash + 16kiB RAM, although devices with at least 512kiB flash + 128kiB RAM allow a much more full-featured experience.

The Unix and Windows ports allow both development and testing of MicroPython itself, as well as providing lightweight alternative to CPython on these platforms (in particular on embedded Linux systems).

The "minimal" port provides an example of a very basic MicroPython port and can be compiled as both a standalone Linux binary as well as for ARM Cortex M4. Start with this if you want to port MicroPython to another microcontroller. Additionally the "bare-arm" port is an example of the absolute minimum configuration, and is used to keep track of the code size of the core runtime and VM.

In addition, the following ports are provided in this repository:

  • cc3200 -- Texas Instruments CC3200 (including PyCom WiPy).
  • esp32 -- Espressif ESP32 SoC (including ESP32S2, ESP32S3, ESP32C3).
  • esp8266 -- Espressif ESP8266 SoC.
  • mimxrt -- NXP m.iMX RT (including Teensy 4.x).
  • nrf -- Nordic Semiconductor nRF51 and nRF52.
  • pic16bit -- Microchip PIC 16-bit.
  • powerpc -- IBM PowerPC (including Microwatt)
  • qemu-arm -- QEMU-based emulated target, for testing)
  • renesas-ra -- Renesas RA family.
  • rp2 -- Raspberry Pi RP2040 (including Pico and Pico W).
  • samd -- Microchip (formerly Atmel) SAMD21 and SAMD51.
  • stm32 -- STMicroelectronics STM32 family (including F0, F4, F7, G0, G4, H7, L0, L4, WB)
  • teensy -- Teensy 3.x.
  • webassembly -- Emscripten port targeting browsers and NodeJS.
  • zephyr -- Zephyr RTOS.

The MicroPython cross-compiler, mpy-cross

Most ports require the MicroPython cross-compiler to be built first. This program, called mpy-cross, is used to pre-compile Python scripts to .mpy files which can then be included (frozen) into the firmware/executable for a port. To build mpy-cross use:

$ cd mpy-cross
$ make

External dependencies

The core MicroPython VM and runtime has no external dependencies, but a given port might depend on third-party drivers or vendor HALs. This repository includes several submodules linking to these external dependencies. Before compiling a given port, use

$ cd ports/name
$ make submodules

to ensure that all required submodules are initialised.